Depletion Mode Field Effect Transistor for ESD Protection

ABSTRACT

The object of this invention is to present a field effect transistor by which the drain capacitance per unit gate width can be reduced. The gate electrode  21  (G) having a plurality of sides is formed in first-conductivity first semiconductor region  14,  drain region  18 D (D) is formed inside the gate electrode, and source regions  18 S (S) are formed in the respective regions outside the plurality of sides in widths that do not reduce the corresponding channel widths of the drain region. The gate electrode is formed along all the plurality of sides of the drain region in order to form a transistor.

FIELD OF THE INVENTION

The present invention pertains to a field effect transistor. In particular, it pertains to a depletion type n-channel MOS field effect transistor that is used in a circuit to protect against electrostatic breakdown of a magnetic head.

BACKGROUND OF THE INVENTION

For example, in the case of a magnetic head, such as a GMR magnetic head, incorporated into a magnetic recording device such as an HDD (hard disk drive), a depletion type n-channel MOS field effect transistor is utilized inside a preamplifier IC as a protective circuit to protect the magnetic head from an electrostatic breakdown.

FIG. 8(A) is a plan view of a depletion type n-channel MOS field effect transistor according to the prior art. As shown in the Figure, gate electrode 41 is formed in a p-type semiconductor region provided on a semiconductor substrate via a gate insulation film, and n-type source region 40S and drain region 40D are formed at surface parts of the p-type semiconductor region at either side part of gate electrode 41. Furthermore, an n-type channel region is formed on the surface part of the p-type semiconductor region immediately below gate electrode 41 so as to form a depletion type n-channel MOS field effect transistor.

Due to increased speeds and capacities of HDDs, there is a demand for depletion type n-channel field effect transistors with lower on resistances in order to improve the performance of ESD protection elements at low capacitances. To realize this, reductions in the on resistance and the drain capacitance are required, and a technique for reducing the on resistance while keeping the drain capacitance unchanged has been adopted.

FIG. 8(B) is a plan view of a depletion type n-channel MOS field effect transistor according to the prior art. Two gate electrodes 41 a and 41 b are formed in a p-type semiconductor region provided on a semiconductor substrate via a gate insulation film; and source region 40Sa, drain region 40D, and source region 40Sb are formed in 3 respective regions that are separated by the two gate electrodes 41 a and 41 b on the surface part of the p-type semiconductor region. N-channel regions are formed in the p-type semiconductor regions immediately below the two gate electrodes 41 a and 41 b so as to form a depletion type n-channel MOS field effect transistor.

As opposed to the field effect transistor with the configuration shown in FIG. 8(A), in the case of the field effect transistor with the configuration shown in FIG. 8(B), because the gate width is set approximately two times as wide while keeping the drain capacitance unchanged, the on resistance is reduced to approximately one half. That is, the drain capacitance per unit gate width is reduced by approximately one half.

However, in recent years, there is a greater demand for faster driving, and further reduction in the on resistance and the drain capacitance is needed. The present invention was devised in light of the aforementioned situation, and its objective is to present a field effect transistor by which the drain capacitance per unit gate width can be reduced.

SUMMARY OF THE INVENTION

In order to achieve the aforementioned objective, the field effect transistor of the present invention has a first-conductivity type first semiconductor region with a channel formation region, a gate electrode that is formed in a pattern with a plurality of sides above the channel formation region of the first semiconductor region on a gate insulation film, a second conductivity type drain region that is formed on the surface part of the first semiconductor region within the inner region of the gate electrode, and second-conductivity type source regions that are formed in the surface layer part of said first semiconductor region in respective regions outside the plurality of sides of the gate electrode in widths that do not reduce the corresponding channel widths of the drain region when looked at from said respective outside regions.

In the aforementioned field effect transistor of the present invention, the gate electrode with the plurality of sides is formed in the first-conductivity type first semiconductor region with a channel formation region, a drain region is formed on the inner side of the gate electrode, and source regions are formed in respective regions on the outer side of the plurality of sides in widths that do not reduce the corresponding channel widths of the drain region. That is, the gate electrode is formed along all the sides of the drain region when the transistor is configured.

Preferably, in the aforementioned field effect transistor of the present invention, the gate electrode is formed repeatedly two-dimensionally in a grid pattern, and drain regions and the source regions are formed alternately and repeatedly two-dimensionally in the inner regions of the aforementioned grids in such a manner that either a drain region or a source region corresponds to a grid. In some instances, the back gates are formed inside the aforementioned first semiconductor region. Furthermore, the back gates and the source regions are connected to each other and a common potential is applied to them.

The field effect transistor of the present invention is used as a switch in a breakdown protection circuit for a magnetic head in order to protect the magnetic head from an electrostatic breakdown.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1(A) is a plan view of the field effect transistor according to a first embodiment of the present invention.

FIG. 1(B) is a cross sectional view along A-B-C in FIG. 1(A).

FIG. 2 is a plan view of a field effect transistor according to a second embodiment of the instant invention.

FIG. 3(A) is a cross sectional view along X-X′ in FIG. 2

FIG. 3(B) is a cross sectional view along Y-Y′ in FIG. 2.

FIG. 4 is a plan view showing the layout of first-layer wirings connected to the source regions, the drain regions, and the back gate regions of the field effect transistor according to the second embodiment of the instant invention.

FIG. 5 is a plan view showing the layout of first-layer wirings that connect the source regions and the back gate regions and second-layer wirings that are formed to connect to respective first-layer wirings that connect the drain regions in the field effect transistor according to the second embodiment of the instant invention.

FIG. 6(A) is a partial cross sectional view of a field effect transistor according to a third embodiment of the instant invention

FIG. 6(B) is a partial cross sectional view of another example according to a third embodiment of the instant invention.

FIG. 7 is a circuit diagram of a circuit for protecting a magnetic head, such as a GMR magnetic head, against electrostatic breakdown (ESD) incorporated into a magnetic recording device.

FIG. 8(A) and FIG. 8(B) are plan views of a depletion type n-channel MOS field effect transistors according to the prior art.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

According to the field effect transistor of the present invention, the gate electrode is formed along all sides of a drain region. The on resistance can be reduced by a quarter with the same drain capacity, that is, the drain capacity per unit gate width can be reduced by a quarter.

Embodiments of the field effect transistor pertaining to the instant invention will be explained below with reference to Figures.

FIG. 1(A) is a plan view of the field effect transistor according to the instant embodiment, and FIG. 1(B) is a cross sectional view along A-B-C in FIG. 1(A). As shown in FIG. 1(B), a first n-type semiconductor layer (n-type tank) 11 is formed in the p-type silicon substrate (p-sub) 10. A second n-type semiconductor layer 12 is then formed on the n-type tank 11. The p-type well (first-conductivity type first semiconductor region) 14 having a channel formation region within an element formation region is formed in the second n-type epitaxial semiconductor layer 12. The p⁺-type buried layer 13 to be used as a back gate is formed at the bottom surface of p-type well 14 at a depth close to the boundary between first n-type semiconductor layer 11 and second n-type semiconductor layer 12. In addition, for example, element-separating insulation film 15 (I) is formed in a prescribed pattern on the surface of p-type well 14 to separate elements from each other. Element-separating insulation film 15 (I) may be formed by means of a LOCOS (local oxidation of silicon) method or an STI (shallow trench isolation) method, for example; and an insulation film formed using the LOCOS method is shown in the figure.

The polysilicon gate electrode 21 (G) is formed in a pattern with a plurality of sides above p-type well 14 having a channel formation region beneath the gate insulation film 20. In addition, a sidewall insulation film 22 is formed on either side part of gate electrode 21 (G). The n⁺-type source region 18S (S) and drain region 18D (D) containing a high concentration of an n-type conductive impurity substance (e.g. arsenic and/or phosphorous) are formed in the p-type well 14 at either side part of sidewall insulation film 22. Here, as shown in FIG. 1(A), gate electrode 21 (G) is formed in a square shape, and drain region 18D (D) is formed within the inner region thereof, whereas source regions 18S (S) are formed in respective regions outside the plurality of sides of gate electrode 21 (G) in widths that do not reduce the corresponding channel widths of drain region 18D (D) when looked at from said respective regions on the outer side. Referring to FIG. 1(B), furthermore, LDD (lightly doped drain) region 17 containing a low concentration of an n-type conductive impurity substance is formed in the p-type well 14 below sidewall insulation film 22 to a depth less than that of the source region 18D and drain region 18D in order to configure a so-called LDD-type source region and drain region. The n-type channel region 16 containing an n-type conductive impurity substance is formed in the p-type well 14 serving as the channel formation region below gate electrode 21 (G). For example, it is formed as a shallow region where a high concentration of As is introduced reducing both the transistor off current and on resistance.

The p³⁰ -type back gate regions 18 BG (BG), which are electrically connected to p⁺-type back gate buried layer 13 are formed in the p-type well 14 corner portions of the gate electrode 21 (G). Back gate regions 18 BG (BG) may be configured in such a manner that while they are separated from source regions 18S (S) by element-separating insulation film 15 (I), the aforementioned gate electrode 21 (G) is extended as far as the boundary regions between back gate regions 18 BG (BG) and source regions 18S (S). In this case, gate electrode 21 (G) takes the shape of a grid.

In addition, for example, inter-layer insulation film 23 made of silicon oxide is formed to cover the aforementioned field effect transistor; opening parts that reach source regions 18S (S), drain region 18D (D), and back gate regions 18BG (BG) are formed; and wires (24S, 24D, and 24 BG) connected to source regions 18S (S), drain region 18D (D), and back gate regions 18 BG (BG) are formed as one body with plugs buried inside the opening parts.

According to the depletion type n-channel MOS field effect transistor of the present embodiment described above, because a gate electrode is formed along all the sides of the drain region, when compared with a field effect transistor that has the same drain region area with a gate electrode along a single side, the on resistance can be reduced by a quarter with the same drain capacity, that is, the drain capacity per unit gate width can be reduced by a quarter using the structure of the instant invention.

In the case of the field effect transistor of the present embodiment configured in the aforementioned manner, wires (24S and 24 BG) are connected, back gate regions 18BG (BG) and source regions 18S (S) are connected, and a common potential is applied. In addition, for example, the field effect transistor of the present embodiment is used as a switch in an electrostatic breakdown protection circuit for a magnetic head in order to protect the magnetic head against electrostatic breakdown.

FIG. 2 is a plan view of a field effect transistor according to a further embodiment of the instant invention. Gate electrodes of the kind pertaining to the first embodiment are repeated two-dimensionally in a grid pattern so as to configure gate electrode G where either a drain region or a source region corresponds to a single grid inside the area of the grid pattern, and drain regions D and source regions S are repeated two-dimensionally. Drain regions D and source regions S are formed in a so-called checkered pattern in the aforementioned manner.

Here, a drain region D is not provided at the outermost circumference. That is, source regions S are formed at the positions corresponding to the sides of a square drain region, and back gate regions BG are laid out between them. As described above, because the sides cannot be used for a drain region at the outermost circumference when configuring the transistor, it is desirable that the outermost region be used for source regions or back gate regions. However, it is also possible to provide drain regions at the outermost circumference.

Although the gate electrode is provided to surround all source regions S and back gate regions BG at the outermost circumferential part in consideration of the ease of removing gate electrode in the aforementioned configuration, the gate electrode between source regions S and back gate regions BG at said outermost circumferential part may be deleted, and back gate regions BG and source regions S may be separated from each other using element-separation insulation film I.

Shown in FIG. 3(A) is a cross sectional view along X-X′ in FIG. 2. As in the first embodiment, for example, first n-type semiconductor layer 11 is formed in p-type silicon substrate 10. The p⁺-type buried layer 13 to be used as the back gate, and a p-type well (first-conductivity type first semiconductor region) 14 with a channel formation region is further formed. In addition, gate electrode 21 (G) made of polysilicon is formed in a grid pattern over the aforementioned p-type well 14 and the channel formation region (16) is formed beneath the gate insulation film 20, and sidewall insulation film 22 made of silicon oxide or silicon nitride is formed on either side part of gate electrode 21. Furthermore, n⁺-type source regions 18S and drain regions 18D are formed alternately and repeatedly in the region inside the grid, and source regions are provided at the outermost circumference. The LDD region 17 is formed in the p-type well 14 below sidewall insulation film 22. The n-type channel region 16 containing an n-type conductive impurity substance such as is formed on the surface part of p-type well 14 serving as the channel formation region below gate electrode 21.

Shown in FIG. 3(B) is a cross sectional view along Y-Y′ in FIG. 2. The configuration shown here is similar to that shown in FIG. 3(A), except that p⁺-type back gate regions 18BG connected electrically to p⁺-type buried layer 13 to be used as back gates are formed at the outermost circumference, and source regions 18S and drain regions 18D are formed alternately and repeatedly in the region between them.

As shown in the Figure, the gate electrode 21 (G) is formed in the shape of a grid, and extends as far as the boundary between back gate region 18BG (BG) and source region 18S (S) in the aforementioned configuration. Here the back gate region 18BG (BG) and source region 18S (S) may be separated from each other using element-separating insulation film 15 (I). The multiple source regions 18S and drain region 18D are connected into a single system, respectively, using wires to be described later, and back gate regions 18BG are further connected to source regions 18S.

FIG. 4 is a plan view showing the layout of a first-layer wiring connected to the source regions, the drain regions, and the back gate regions of the field effect transistor pertaining to the present embodiment. Upper-layer wirings (24S, 24D, and 24BG) are formed via contacts CT with respect to source regions S, drain regions D, and back gate regions BG. Source regions S are connected into a single system using wiring 24S; and because wiring 24 BG is connected to wiring 24S, source regions S are connected into a single overall system with back gate regions BG. The drain regions D are divided into sections where they can be connected to each other between wirings 24S, that is, into multiple systems in the figure, and they are connected to wiring 24D.

FIG. 5 is a plan view showing the layout of first-layer wirings that connect the source regions and the back gate regions, the second-layer wirings are formed to connect to respective first-layer wirings that connect the drain regions in the field effect transistor pertaining to the present embodiment. The first-layer wirings 24D divided into multiple sections and are all connected together into a single system by second-layer wirings 25D. In addition, while wirings 24S (wirings 24 BG) are already connected into a single system, in this case, the wiring resistance is reduced by second-layer wirings 25S when they are connected into the system. Furthermore, for example, the second wirings (25S and 25D) may be formed in regions other than those shown above in order to reduce the wiring resistance.

In the aforementioned configuration, the source regions and the drain regions are divided into multiple sections in a so-called a checkered pattern, and the gate electrode is provided at grid-like boundaries between the respective source regions and the drain regions. As such, while the source regions and the drain region that are adjacent to each other via the gate electrode constitute the field effect transistor, the respective source regions and the drain regions are put together into a single system and a single depletion type n-channel MOS field effect transistor is configured as a whole.

In comparison to a field effect transistor that has the same drain region area but only a single drain region, the aforementioned depletion type n-channel MOS field effect transistor of the present embodiment is equivalent to one in which the gate width of the transistor is significantly widened. As such, the on resistance can be reduced with the same drain capacitance, that is, the drain capacitance per unit gate width can be reduced.

In the aforementioned field effect transistors of the first embodiment and the second embodiment, the back gate regions are separated from the source regions by an element-separating insulation film, or the gate electrode extends as far as the boundaries between the back gate regions and the source regions, and the source regions and the back gate regions are connected using upper-layer wirings. However, when connection of the source regions to the back gate regions is assumed, there is no need to divide the source regions and the back gate regions into separate regions using the element-separating insulation film. In the case of the field effect transistor of the present embodiment, the source regions and the back gate regions are provided next to each other without separating them using an element-separating insulation film.

Shown in FIG. 6(A) is a partial cross sectional view of a field effect transistor according to a further embodiment of the instant invention. As shown in FIG. 3(A), gate electrodes 21 are formed in a grid pattern, n⁺-type source regions 18S and drain regions 18D are formed in the inner regions of the respective grids alternately and repeatedly, and source regions 18S are provided at the outermost circumference.

As shown in FIG. 6(A), p⁺-type back gate regions 18BG are provided adjacent to source regions 18S provided at the outmost circumference without separating them using an element-separating insulation film. In this case, contacts common to respective source regions 18S and back gate regions 18BG can be used to connect them to an upper-layer wiring. Source regions 18S and back gate regions 18BG provided adjacent to each other without an element-separating insulation film as in the aforementioned manner can be formed by providing a mask opening part for implanting an n-type impurity to form source regions 18S and a mask opening part for injecting an p-type impurity substance so as to form back gate regions 18BG adjacent to each other, that is, by injecting impurity substances into adjoining regions.

Shown in FIG. 6(B) is a partial cross sectional view of another example of a field effect transistor according to a further embodiment of the instant invention. As shown in the Figure, in a configuration in which n⁺-type source regions 18S and drain regions 18D are repeated alternately, p⁺-type back gate regions 18BG are provided adjacent to regions further inside source regions 18S without separation using an element-separating insulation film with respect to source regions 18S in regions sandwiched by drain regions 18D. Similarly, source regions 18S and back gate regions 18BG may be connected using common contacts common to them, and said structure can be formed by implanting respective impurity substances into adjoining regions. The configuration of the present embodiment can be applied to the aforementioned respective embodiments. Furthermore, because the back gate regions for establishing connections to the back gates can be laid out adjacent to the source regions, the element area of the structure is reduced.

FIG. 7 is a circuit diagram of a circuit for protecting a magnetic head against electrostatic breakdown (ESD) and is used for a magnetic head, such as a GMR magnetic head, incorporated into a magnetic recording device. The field effect transistors in the aforementioned respective embodiments can be used as a switch element of the protective circuit. For example, magnetic head 30, such as a GMR magnetic head, is connected to preamplifier 32 via line 31 a and line 31 b. Here, field effect transistors 33 and 34 are connected to line 31 a and line 31 b, respectively, to serve as ESD protection circuits. The ESD protection circuits are configured using the aforementioned depletion type n-channel field effect transistors with the aforementioned respective embodiments, their drain regions are connected to lines 31 a and 31 b, and their source regions are connected to a reference potential (for example, ground).

Because the ESD protection circuits become conductive when an excessive voltage is applied to lines 31 a and 31 b so as to release said excessive voltage to the reference potential, a negative potential is applied to gate terminals 33 a and 34 a of the depletion type field effect transistors 33 and 34 to keep transistors 33 and 34 non-conductive while under the steady state. A bias current is supplied to magnetic head 30 through a path comprising a positive-side power supply, line 31 a, magnetic head 30, line 31 b, and a negative-side power supply. At this time, the voltage of the positive-side power supply is +3V to +5V, and the voltage of the negative-side power supply is −2V to −5V. In this case, gate electrodes 33 a and 34 a of field effect transistors 33 and 34 may be connected to the negative-side power supply. In addition, a voltage difference of roughly 100 mV is created between line 31 a and line 31 b, that is, across the two ends of magnetic head 30.

While preamplifier 32 and field effect transistors 33 and 34 can be formed on a single semiconductor integrated circuit (IC), magnetic head 30 is attached to said semiconductor integrated circuit externally.

The present invention is not restricted to the explanation given above. For example, a silicide layer may be formed partially or entirely over the surfaces of the source regions, the drain regions, the back gate regions, and the gate electrode. For example, it can be formed over the entire surfaces of the source regions, the drain regions, the back gate regions, and the gate electrode by means of siliciding process. Although depletion type field effect transistors were explained in the aforementioned embodiments, application to an enhancement type by not forming a channel region is also possible. In addition, although an n-channel depletion mode field effect transistor was explained, application to a p-channel depletion mode field effect transistor is also possible by simply reversing the n-type and p-type regions of the structures shown in the Figures. 

1. Claim 1 is a field effect transistor, comprising: a semiconductor region of a first conductivity type with a channel formation region; a gate electrode that is formed in a pattern with a plurality of sides on a gate insulation film above the channel formation region of the first semiconductor region; a drain region that is formed in the first semiconductor region within an inner region of the gate electrode; and second-conductivity type source regions that are formed in the first semiconductor region in regions opposite to said inner region of the gate electrode in predetermined widths.
 2. The field effect transistor of claim 1, wherein the gate electrode is formed in a two-dimensional grid pattern, and the drain region and the source region are formed alternately and repeatedly in two dimensions in regions of the two-dimensional grid pattern.
 3. The field effect transistor of claim 2, wherein back gates are formed in the first semiconductor region.
 4. The field effect transistor of claim 3, wherein the back gates and the source regions are connected to each other, and a common potential is applied to them.
 5. The field effect transistor of claim 4, wherein the first-conductivity type is p-type and the second-conductivity type is n-type.
 6. The field effect transistor of claim 5, wherein a second-conductivity type channel region is formed in the channel formation region of the semiconductor region.
 7. An ESD depletion mode field effect transistor, comprising: a semiconductor layer of a first conductivity type formed on a semiconductor substrate; a square drain region of a second conductivity type formed in the first semiconductor layer; a plurality of source regions of a second conductivity type formed in first semiconductor layer at a predetermined distance from the drain region; a grid-shaped gate electrode formed on a gate insulating layer above a channel region of the first semiconductor layer, which is positioned between the drain region and the multiple source regions and surrounding the drain region, wherein the multiple source regions are provided at positions that correspond to respective sides of the drain region; and the multiple source regions are connected to each other electrically.
 8. The transistor of claim 7 further comprising: the drain region, the multiple source regions, and the gate electrode all formed in a repetitive pattern; the drain regions formed in the repetitive pattern being connected to each other electrically; and the multiple source regions formed in the repetitive pattern being connected to each other electrically.
 9. The transistor of claim 7 further comprising: a back gate region of a first conductivity type formed in the first semiconductor layer; and the multiple source regions and the back gate region connected to each other electrically.
 10. The transistor of claim 9, wherein the channel region comprises a first-conductivity type semiconductor layer formed in the first semiconductor layer.
 11. The transistor of claim 10, wherein the first-conductivity type is p-type and the second-conductivity type is n-type. 